NL8105196A - DIFFERENTIAL PULSE CODE MODULATION TRANSFER SYSTEM. - Google Patents

Abstract

Differential pulse code modulation transmission system in which the transmitter and the receiver each comprise a prediction circuit for generating a prediction signal from the transmitted DPCM-signal. This prediction circuit is in the form of two or more prediction channels 710(i) each consisting of a non-linear network 711(i) followed by a leaky integrator circuit 700(i). The inputs of these prediction channels are connected to a common input 701 and the output of each prediction channel is connected to an input of a summing device 712, which produces the desired prediction signal.

Description

* 1 - »ΕΗΝ 10,192. 1 N.V. Philips' Gloeilampenfabrieken in Eindhoven "Differential Pulse Modulation Transfer System" A. Back of the invention. R). Area of the invention

The invention relates to a transmission system, provided with a transmitter and a receiver, for transmission of an information signal, in particular a video signal, in a digital format obtained by means of differential pulse code modulation (DPCM). The transmitter of this system is provided with a DPCiHooder device and the receiver with a DPCM decoder.

10 A (2). Description of the prior art

The transmitter of a transmission system generally includes an Iron which provides an information signal in analog or digital form and which is transmitted to the cooperating receiver. In a DPCM transmission system, this information signal is first applied to a hron encoder which is here implemented as a DPCM encoder. It contains a difference generator to which the information signal and a prediction signal are applied and which provides a difference signal. This difference signal is supplied to a quantizer which provides a quantized difference signal. The DPCM encoder further includes a pre-thickness circuit with an input and an output. The quantized difference signal is applied to the input of this prediction circuit and the said prediction signal 25 cp.

The quantized difference signal occurring at the output of the quantizer is further applied to a channel encoding circuit, for example an analog-digital crozetter or a code converter, which converts this quantized difference signal into a digital channel signal which will be called DPCM signal and which consists of a sequence of code words that occur at a certain rate fg / also called sampling frequency. It should be noted that the inverse quantity 1 / fg sampling period will be called and will be 8305196 V v * EHN 10.192 2 denoted by the symbol T.

The codewords supplied by the channel coding circuit were transferred via a transmission medium to the cooperating receiver, where the series of codewords received in a channel-5 coding circuit is converted into a decoded channel signal which, on undisturbed transmission, accurately corresponds to the original quantized difference signal. This decoded channel signal is further supplied to a DKM decoder. It is provided with a transformer to which the decoded channel signal 10 and a second prediction signal are applied and which provides a sum signal. This DPCM decoder also contains a second prediction circuit with an input and an output, the decoded channel signal being applied to its input and the second prediction signal occurring at its output. The prediction circuit in the transmitter is structured in the same manner as in the receiver in order to ensure that the sum signal accurately corresponds to the original information signal.

A prediction circuit can be implemented in several ways. Possible implementations are described in 20 eg the references 1, 2, 3r 4, 5 and 6. As these references show, such a prediction circuit is generally formed by an integrator circuit, the input of which is connected to d <5: input of the prediction circuit and the output of which is connected qp the output of the prediction circuit.

In the receiver, each code word received now contributes for a certain time interval to the formation of the scan signal. If a code word is now disturbed in the transmission medium, the sansignal is also disturbed for an equally long time interval.

This time interval is closely related to the time constant of the integrator circuit. If it has an infinitely long time constant (in this case it is called an ideal integrator circuit), the scnr signal will never get the correct value again after a transmission error has occurred. In such a case, it is common to set the prediction circuit of DPCM encoder and decoder periodically (eg, at the end of each TV line) to a fixed value.

If the time constant of the integrator circuit is chosen to be smaller (in this case it is called a leaking 8105196

Claims (2)

1. Differential Pulse Code Modulation (DPCM) transmission system that includes a transmitter and a receiver, where: A. The transmitter is equipped with: a.1. means for generating an information signal to be transmitted; a. 2. A DPCM encoder containing: aa.1. a differential vessel to which the first information signal to be transmitted is supplied via a first input and a first prediction signal via a second input in order to generate a difference signal; aa.2. a quantizer to which the difference signal is applied and which provides a quantized difference signal? aa.3. a first prediction circuit for generating the first prediction signal and comprising an input to which the quantized difference signal is applied, and an output coupled to the second input of the difference generator; a. 3. a channel coding circuit for converting the quantized difference signal into a digital channel signal. B. the recipient is provided with: b. 1. a channel decoding circuit for converting the received digital channel signal into a decoded channel signal; b.2. a DPCM® encoder containing: 25 bb. 1. a reformer to which the decoded channel signal has been applied via a first input and a second prediction signal via a second input; bb.2. a second prediction circuit for generating the second prediction signal and comprising an input to which the decoded channel signal is applied, as well as an output coupled to the second input of the reformer; b. 3. means for processing the sansignal supplied by the sanformer; C. the first and second prediction circuits are each formed by two or more prediction channels each consisting of a non-linear network followed by a leaky integrator circuit, the input of each non-linear network being connected to the input of 810 5 1 δ 6 ft * a BHN 10.192 14 the prediction circuit, which integrator circuits are all structured in the same manner, each integrator circuit associated with a unique set of weighting factors, the integrator circuits of which the outputs are connected to 5 inputs of an adder whose output is connected to the output of the preaching circuit. The transmission system of claim 1, wherein for the prediction channel with rank number i the relationship between the input signal d (n) of the non-linear network and its output signal 10 b (i; n) is given by the expression "0 for | d (n) (^ A (i-1) b (i; n) = sign {d (n)} · f3 (n) j - A (i-1)] for A (i-1) <jd ( n) | £ A (i) bsign (d (n)} A (i) - A (i-1) J for | d (n) [> A (i) 15 herein A (i) represents a positive difference vocar net A (Q) = 0 and A (i + 1)> A (i) and signfd (n)] represents the polarity of d (n) 20 25 30 8 105 106> 35